Download HOMEWORK ASSIGNMENT 5: Solutions

PHYS852 Quantum Mechanics II, Spring 2010
HOMEWORK ASSIGNMENT 5: Solutions
Topics covered: rotation with spin, exchange symmmetry
1. The Hamiltonian for the deuteron, a bound-state of a proton and neutron, may be written in the
form
Pp2
P2
~p · S
~n ,
H=
+ n + V1 (R) + V2 (R)S
(1)
2Mp 2Mn
where R is the relative radial coordinate. Both are spin-1/2 particles, but they are not identical.
~=S
~p + S
~n . The state |sp sn s mi is the simultaneous
(a) The total angular momentum operator is S
~p , S
~n , S 2 , and Sz . What are the allowed values of the total spin quantum number
eigenstate of S
s? For each s-value, what are the allowed m quantum numbers.
With sp = 1/2 and sn = 1/2, we find smin = |sp − sn | = 0, and smax = sp + sn = 1, so the
allowed values of s are 0, 1. For s = 0, only m = 0 is allowed, while for s = 1, we can have
m = −1, 0, 1.
~p · S
~n , and give the corresponding eigenvalue. Hint, use
(b) Show that |sp sn s mi is an eigenstate of S
2
~
~
~
~
the fact that S = (Sp + Sn ) · (Sp + Sn ).
We have
~p · S
~n + Sn2
S 2 = Sp2 + 2S
(2)
~p · S
~n gives
solving for S
~p · S
~n = 1 S 2 − S 2 − S 2
S
p
n
2
(3)
~p · S
~n with
As |sp sn smi an eigenstate of S 2 , Sp2 andSn2 , then it must also be an eigenstate of S
2
eigenvalue ~2 (s(s + 1) − 3).
(c) Give ten distinct quantum numbers that can be assigned to an eigenstates of this H. Note that
this includes sp and sn , even though they can never change.
The ten quantum numbers are the three components of the center-of-mass momentum: px , py ,
and pz ; the orbital quantum numbers of the relative motion:n, `, and m` ; and the four spin
quantum numbers: sp , sn , s, and m.
(d) What one-dimensional wave equation would you have to solve to find the energy eigenvalue
associated with one of these states?
The radial wave equation would be:
2 2
~ d
~2 `(` + 1)
~2
−
+
+ V1 (r) +
[s(s + 1) − 3] V2 (r) − En`s Rn`s (r) = 0
(4)
2µ dr2
2µr2
2
1
2. Consider a particle of spin s = 1, constrained to move on the surface of a sphere. Assume that the
Hamiltonian of the particle is
~ ·S
~
L2 L
H=
+
,
(5)
2I
I
~ is the orbital angular momentum operator, I is the moment of inertia, and S
~ is the spin
where L
operator. find the quantized energy levels and the degeneracy of each level.
~ + S,
~ simultaneous eigenstates of H, L2 , S 2 , J 2 , and Jz exist. We can label the |`sjmj i,
With J~ = L
as s = 1 never changes, we can drop s. We have then
2
~ `(` + 1) ~2
H|`jmj i =
+
[j(j + 1) − `(` + 1) − s(s + 1)] |`jmj i
2I
2I
~2
=
[j(j + 1) − 2] |`jmj i
(6)
2I
so we see that energy depends on j only. This means that states with the same j but different ` are
degenerate. The degeneracy factor 2j + 1 counts only those states with the same j for fixed `. We
therefore need to multiply by the number of `-values that can give a specific j value to get the total
degeneracy of the j th energy level. The easiest way to do this is to make a table:
`
0
1
2
3
..
.
jmin
1
0
1
2
..
.
jmax
1
2
3
4
..
.
It is easy to see that j = 0 can only occur when ` = 1, j = 1 can occur for ` = 0, 1, 2, j = 3 for
` = 2, 3, 4, etc... So the number of `-values for a given j is 3, except for j = 0 which has only 1. This
can be formulated as dj = (2j + 1)(3 − 2δj,0 ) = 6j + 3 − 2δj,0
2
3. For Silicon, the ground-state configuration is (3p)2 , i.e. there are two valence electrons, each in the
3p state.
~=S
~1 + S
~2 ?
(a) What are the possible values for the total spin quantum number, s, where S
s = 0, 1
~ =
(b) What are the possible values for the total angular momentum quantum number, `, where L
~1 + L
~ 2?
L
`1 = 1, `2 = 1, so ` = 0, 1, 2.
(c) The exchange symmetry of the two-electron spatial wavefunction matches the parity of the
quantum number `. Based on this, determine which combinations of s and ` are allowed states
for the two-electron system.
s = 0 is odd under exchange, while s = 1 is even. For `, we have the opposite, ` = 0 is even,
` = 1 is odd, and ` = 2 is even.
The totally anti-symmetric combinations are therefore (s, `) = (0, 0), (1, 1), (0, 2)
(d) For each allowed combination, what are the possible values of the quantum number j, where
~ + S?
~
J~ = L
For (s, `) = (0, 0) we can only have j = 0. For (s, `) = (1, 1), we can have j = 0, 1, 2, and for
(s, `) = (0, 2) we can only have j = 2.
(e) Assuming that the spin-orbit interaction lifts the degeneracy of the states with different j, how
many distinct energy levels make up the fine-structure of the (3p)2 state?
The allowed j values are j = 0, 1, 2, so there would be 3 fine-structure levels.
(f) Which j levels would shift if a contact interaction between the two valence electrons were added
to the Hamiltonian?
Only states with even orbital exchange symmetry would be affected by a zero-range potential,
i.e. ` = 0 or ` = 2. This means only the j = 0 an j = 2 levels would shift.
3
~ + S.
~ Using the method described in the lecture, identify and calculate all non-zero
4. Let J~ = L
Clebsch-Gordan coefficients for the ` = 2, s = 1/2 case.
For starters, we need jmax = ` + s = 2 + 12 = 52 and jmin = |2 − 21 | = 32
Starting from |5/2, 5/2i = |2, 1/2i, we apply J− = L− + S− to get
r
J− |5/2, 5/2i = L− |2, 1/2i + S− |2, 1/2i
√
5 7 5 3
· − · |5/2, 3/2i =
2 · 3 − 2 · 1|1, 1/2i + |2, −1/2i
2 2 2 2
√
5|5/2, 3/2i = 2|1, 1/2i + |2, −1/2i
2
1
|5/2, 3/2i = √ |1, 1/2i + √ |2, −1/2i
5
5
Applying J− again gives
r
5 7 3 1
· − · |5/2, 1/2i =
2 2 2 2
√
8|5/2, 1/2i =
|5/2, 1/2i =
2 √
1 √
√
2 · 3 − 1 · 0|0, 1/2i + |1, −1/2i + √ 2 · 3 − 2 · 1|1, −1/2i
5
5
√
2 6
4
√ |0, 1/2i + √ |1, −1/2i
5
5
√
√
3
2
√ |0, 1/2i + √ |1, −1/2i
5
5
After this point, the remaining terms can be found by symmetry, giving:
j, mj
5/2,5/2
5/2,3/2
5/2,1/2
5/2,-1/2
5/2,-3/2
5/2,-5/2
3/2,3/2
3/2,1/2
3/2,-1/2
3/2,-3/2
Table 1: Clebesh Gordan coefficients: h2, 1/2, m` , ms |j, mj i
m` , ms
2,1/2 2,-1/2 1,1/2
1,-1/2
0,1/2
0,-1/2
-1,1/2
1
0√
0√
0
0
0
0
0
1/ 5 2/ 5 √ 0√
0
0
0
√ √
0
0
0
2/ 5
3/ 5 √ 0√
√ 0√
0
0
0
0
0
3/ 5
2/ 5
0
0
0
0
0
0
0
0
0√
0√
0
0
0
0
0
2/ 5 −1 5 √ 0√
0
0
√0 √
0
0
0
3 5 − 2/ 5 √ 0√
√0 √
0
0
0
0
0
2/ 5 − 3/ 5
0
0
0
0
0
0
0
4
-1,-1/2
0
0
0
0√
2/ 5
0
0
0
0√
1/ 5
-2,1/2
0
0
0
0√
1/ 5
0
0
0
0√
−2/ 5
-2,-1/2
0
0
0
0
0
1
0
0
0
0